JP6524231B2 - Fire door - Google Patents

Description

  The present invention relates to a fire door installed in a building.

  BACKGROUND ART Conventionally, fire doors installed in commercial facilities and buildings such as hospitals are known. The fireproof door described in Patent Document 1 as an example thereof includes a door having a form as a sliding door, a drive unit for driving the door, and a case accommodating the drive unit.

JP-A-8-284544

  When a fire occurs in a building where fire doors are installed, the heat of the flame is transferred to the case and the temperature inside the case rises. For this reason, the temperature of the drive part accommodated in the case tends to rise. In addition, it is thought that the same subject arises not only in the sliding door of patent document 1 but the fire door which has a form as an open door or a folding door arises.

  An object of the present invention is to provide a door in which the temperature of the drive unit is less likely to rise.

  (1) A fire prevention door according to an aspect of the present invention includes a drive unit for driving a door, a case accommodating the drive unit, and a heat insulating material supported by the case outside the case.

  According to this fireproof door, when a fire occurs in a building in which the fireproof door is installed, heat transfer from the flame to the case is suppressed by the heat insulating material, so the temperature inside the case rises. Hateful. For this reason, the temperature of the drive unit does not easily rise.

(2) According to the form subordinate to the above-mentioned fire lock door, it is provided with a plurality of the above-mentioned heat insulation materials, and a plurality of the above-mentioned heat insulation members are laminated in the front-back direction of the above-mentioned fire lock door.
According to this fireproof door, an air layer is formed between the adjacent heat insulation materials by laminating the plurality of heat insulation materials in the front-rear direction, that is, the indoor and outdoor directions divided by the fireproof doors. For this reason, in addition to the heat insulation effect by a heat insulating material, since the heat insulation effect by an air layer is acquired, the temperature of a drive part is more difficult to rise.

  (3) According to one mode subordinate to the above-mentioned fire lock door, it further comprises a holding member formed of a metal having a thermal conductivity lower than that of mild steel, and the holding member is disposed between the case and the heat insulating material. The heat insulating material is supported by the case via the holding member.

  According to this fireproof door, since the holding member formed of a metal having a thermal conductivity lower than that of the soft steel is disposed between the case and the heat insulating material, heat transfer to the case via the holding member is suppressed. It is possible to suppress the temperature rise inside the case. For this reason, the temperature of the drive unit does not easily rise.

(4) According to one mode subordinate to the fire door, the holding member is attached to the side wall of the case.
Since the longitudinally extending side wall of the case is a portion facing the room or the outside, when a fire occurs in a building where a fire door is installed, it is easily exposed to a flame. According to this fireproof door, since the holding member is attached to the side wall of the case, the heat insulating material is disposed at a position facing the side wall. As described above, since the heat insulating material is disposed at a portion of the fire door that is easily exposed to the flame, the temperature of the drive unit is less likely to rise.

(5) According to one mode subordinate to the fire door, at least one of the heat insulating material and the holding member is shaped to extend along the side wall of the case.
According to this fire door, since at least one of the heat insulating material and the holding member is shaped to extend along the side wall of the case, at least one of the heat insulating material and the holding member is disposed at a position facing a wider portion of the case. Be done. For this reason, the temperature of the drive unit is less likely to rise.

(6) According to one mode subordinate to the fire door, the holding member is configured to hold the shape of the heat insulating material.
According to this fireproof door, since the holding member is configured to maintain the shape of the heat insulating material, the shape of the heat insulating material is easily maintained. For this reason, it can suppress that a heat insulating material is exposed to a flame, a shape collapse | crumbles, and the heat insulation performance of a heat insulating material falls.

  (7) According to one mode subordinate to the fire door, the holding member is a holding portion which is a portion disposed between the case and the heat insulating material, and the holding portion of the heat insulating material And a protection portion facing the surface opposite to the surface held by the

  According to this fireproof door, the protective portion suppresses direct exposure of the heat insulating material to the flame, so the shape of the heat insulating material is easily maintained. For this reason, it can suppress that a heat insulating material is exposed to a flame, a shape collapse | crumbles, and the heat insulation performance of a heat insulating material falls.

(8) According to one mode subordinate to the above-mentioned fire door, the above-mentioned protection part is a shape prolonged along the side wall of the above-mentioned case.
According to this fireproof door, since the protection portion is shaped to extend along the side wall of the case, a wider portion of the surface of the heat insulating material exposed to the flame can be covered by the protection portion. Therefore, the shape of the heat insulating material can be more easily maintained.

(9) According to one mode subordinate to the above-mentioned fire lock door, a plurality of the holding members are provided, and the plurality of holding members are arranged at intervals.
According to this fireproof door, since the heat insulating material is supported by the case via the divided holding members, weight reduction of the fireproof door is achieved.

  (10) A fire door according to an aspect of the present invention is formed of a metal having a thermal conductivity lower than that of mild steel, and further includes a partition plate disposed inside the case at a distance from the inner surface of the case.

  According to this fireproof door, since the air layer is formed between the inner surface of the case and the partition plate, the heat transfer inside the case is hindered by the air layer. In addition, since the partition plate is formed of a metal having a thermal conductivity lower than that of mild steel, heat is less likely to be transmitted inside the case. For this reason, the temperature of the drive unit does not easily rise.

  (11) According to one mode subordinate to the above-mentioned fire lock door, a drive unit for driving a door, a case accommodating the drive unit, and a heat insulating material supported by the case inside the case Prepare.

  According to this fireproof door, when a fire occurs in the installed building, the heat insulating material suppresses that the heat of the flame transmitted to the case is transmitted in the space inside the case. For this reason, the temperature of the drive unit does not easily rise.

  According to some aspects of the invention, there is provided a door in which the temperature of the drive unit is less likely to rise. Other aspects and advantages of the present invention will become apparent from the following description taken in conjunction with the drawings illustrating an example of the technical concept of the present invention.

The front view of the appearance of the fire lock door of an embodiment. FIG. 2 is a cross-sectional view taken along line D2-D2 of FIG. Sectional drawing in alignment with the D3-D3 line of FIG. The disassembled perspective view of the heat insulation part of the fire door of FIG. The perspective view of the heat insulation part of FIG. The blind sectional view of a modification. The blind sectional view of a modification. The blind sectional view of a modification. The blind sectional view of a modification. The blind sectional view of a modification. The blind sectional view of a modification. The blind sectional view of a modification. The disassembled perspective view of the heat insulation part of a modification. The disassembled perspective view of the heat insulation part of a modification. The disassembled perspective view of the heat insulation part of a modification. The disassembled perspective view of the heat insulation part of a modification. The blind sectional view of a modification. The blind sectional view of a modification. The blind sectional view of a modification. The blind sectional view of a modification. The blind sectional view of a modification. The disassembled perspective view of the heat insulation part of a modification. The disassembled perspective view of the heat insulation part of a modification. The disassembled perspective view of the heat insulation part of a modification. The disassembled perspective view of the heat insulation part of a modification. The perspective view of the heat insulation part of a modification.

(Embodiment)
As shown in FIG. 1, the pull-out type fire door 1 has a pair of vertical frames 2 disposed opposite to each other in the longitudinal direction of the frontage 100 formed in the building, and a pair of vertical frames 2 above There is provided a blind 40 arranged and fixedly supported by the pair of vertical frames 2. The fire door 1 further includes two fixed walls 10 and two sliding doors 20 moving along the direction in which the two fixed walls 10 are arranged. In the blind 40, a drive unit 30 for moving the sliding door 20 is accommodated, and when the driving unit 30 moves the sliding door 20 in the driving direction ZB, an entrance / exit between the two fixed walls 10 of the two sliding doors 20 Open and close. The fire door 1 may be a single pull type that includes one fixed wall 10 and one sliding door 20 driven by the drive unit 30. Moreover, the sliding door 20 is an example of a door, and may be called a door leaf. The fire door 1 may be provided with an open door driven by the drive unit 30 or a folded door driven by the drive unit 30 instead of the sliding door 20.

  The vertical frame 2 is formed of mild steel or stainless steel. The fixed wall 10 includes a middle standing 11 extending in the height direction ZA of the fire door 1 and a base 12 disposed between the middle standing 11 and the vertical frame 2 and extending in the driving direction ZB of the sliding door 20. The vertical frame 2, the center frame 11, the baseboard 12 and the blind 40 support the heat-resistant glass panel 13.

  The sliding door 20 includes a rectangular frame 21 formed of mild steel or stainless steel, and a heat-resistant glass panel 22 supported by the frame 21. The sliding door 20 is suspended by a traveling rail (not shown) disposed in the blind 40 through door hangers 81 and 82 having door wheels, and is slidably supported in the driving direction ZB.

  Drive unit 30 is disposed spaced from drive sprocket 32 in drive direction ZB of electric motor 31, an output shaft of electric motor 31 and a reduction gear (not shown) and a drive sprocket 32 and sliding door 20. A driven sprocket 33, and a chain 34 wound around a drive sprocket 32 and the driven sprocket 33. The chain 34 has a first portion 34A and a second portion 34B which move in different directions. The first portion 34A and one frame 21 of the two sliding doors 20 are connected via a first door hanger 81. The second portion 34 B and the other frame 21 of the two sliding doors 20 are connected via a second door hanger 82. The driving force of the electric motor 31 is transmitted to the door hangers 81 and 82 through the chain 34, whereby the sliding door 20 opens and closes. In addition, it is an automatic for moving the sliding door 20 in the closing direction when it is detected that a fire has occurred in the building where the fire door 1 is installed in addition to the drive unit 30 in the blind 40 A closure device (not shown) is arranged.

  As shown in FIG. 2, the blind 40 is fixedly supported by the bolts 90 to the pair of vertical frames 2 and is suspended by an anchor (not shown) of a housing. The blind 40 has a main case 50 accommodating the drive unit 30, a sub case 60 attached to the bottom wall 50A of the main case 50, and an inspection attached to one side wall 50B of the main case 50 via a hinge 41. A cover 42 is provided. The blind 40 further includes a cosmetic cover 43 covering the other side wall 50C of the main case 50, and a heat insulating portion 70 disposed between the cosmetic cover 43 and the side wall 50C of the main case 50. In addition, in FIG. 2, in order to simplify the drawing, an area in which the drive unit 30 is disposed is indicated by a two-dot chain line, and the illustration of the fixed wall 10 is omitted.

  Main case 50 is formed of mild steel, and a portion of bottom wall 50A and side wall 50B is open. By opening the inspection cover 42 attached to the side wall 50B, the worker can perform maintenance of the parts constituting the drive unit 30 through the opening formed in the side wall 50B. The bottom wall 50A, the side walls 50B and 50C, and the top wall 50D of the main case 50 are shaped to extend in the driving direction ZB of the sliding door 20.

  Inside the main case 50, a flat bar 51 for enhancing the strength of the main case 50 is disposed. The flat bar 51 is a plate-like member extending downward from the upper wall 50D of the main case 50, and is formed of mild steel. A first partition plate 52 made of stainless steel and extending in the height direction ZA of the fire door 1 is attached to the side surface 51A of the flat bar 51 facing the drive portion 30. A space is formed between the upper end of the first partition plate 52 and the upper wall 50D. A second partition plate 53 formed of stainless steel is attached between the side surface 51B opposite to the side surface 51A of the flat bar 51 and the inner surface of the side wall 50C. The second partition plate 53 is bent in a U-shape, and can accommodate the wiring of the drive unit 30, the wirings of various sensors attached to the fire door 1, and the like. The second partition plate 53 is disposed above the drive unit 30 in the space inside the main case 50. In the space inside the main case 50, an air layer 54 is formed in a space surrounded by the first partition plate 52 and the second partition plate 53. The air layer 54 is formed below the second section plate 53 shown in FIG. 3 along the longitudinal direction of the second section plate 53, that is, the driving direction ZB of the sliding door 20. The air layer 54 may be formed in the space inside the main case 50 by omitting the second partition plate 53 and bringing the upper end of the first partition plate 52 into contact with the upper wall 50D.

  The sub case 60 is made of, for example, stainless steel, and is welded to the bottom wall 50A of the main case 50. The sub case 60 has a hollow rectangular parallelepiped shape in which the top wall 60A is connected to the bottom wall 50A and extends in the driving direction ZB (see FIG. 1) of the sliding door 20. Two heat insulating materials 61 are stacked in the sub case 60 in the height direction ZA of the fire door 1. The heat insulating material 61 is a plate-like member formed mainly of calcium silicate and extending in the driving direction ZB (see FIG. 1) of the sliding door 20. The number of heat insulating materials 61 disposed inside the sub case 60 may be one or three or more. Moreover, the heat insulating material 61 should just be a member which has heat insulation performance, such as a gypsum board etc. which were formed in plate shape which has gypsum as a main component. The inspection cover 42 and the cosmetic cover 43 are made of stainless steel, but may be made of other metals such as mild steel.

  As shown in FIGS. 2 and 3, the heat insulating portion 70 is a holding member 72 that accommodates two heat insulating materials 71 and two heat insulating materials 71 stacked in the front-rear direction ZC of the fire door 1. Equipped with In addition, the front-back direction ZC of the fire door 1 is the indoor / outdoor direction divided by the fire door 1 in the building where the fire door 1 is installed.

  The heat insulating material 71 is a plate-like member formed mainly of calcium silicate and extending in the driving direction ZB (see FIG. 3) of the sliding door 20. The heat insulating material 71 is supported by the main case 50 via the holding member 72 outside the main case 50. The heat insulating material 71 is disposed on the opposite side of the inspection cover 42 in the front-rear direction ZC of the fire door 1. The number of heat insulating materials 71 disposed inside the holding member 72 may be one or three or more. Moreover, the heat insulating material 71 should just be a member which has heat insulation performance, such as a gypsum board etc. which were formed in plate shape which has gypsum as a main component.

  As shown in FIG. 4, the two heat insulating materials 71 are respectively joined with heat insulating materials having different longitudinal dimensions. For this reason, a joint 71A is formed on one of the two heat insulating materials 71, and a joint 71B is formed on the other heat insulating material 71. In the drive direction ZB of the sliding door 20, the position of the joint 71A and the position of the joint 71B are different. The joints 71A and 71B are formed because the dimension in the driving direction ZB of the sliding door 20 of the main case 50 (see FIG. 3) is longer than the length of the heat insulating material 71 in the longitudinal direction.

As shown in FIG. 2, the holding member 72 is made of, for example, stainless steel, and has a holding portion 73 and a protection portion 74 combined with each other.
The holding portion 73 has a side wall 73A disposed between the side wall 50C of the main case 50 and the heat insulating material 71, and an upper wall 73B and a bottom wall 73C protruding forward of the fire door 1 from the side wall 73A.

  The side wall 73A, the top wall 73B, and the bottom wall 73C are shaped to extend in the driving direction ZB of the sliding door 20, and the longitudinal dimension is the longitudinal dimension of the heat insulating material 71 and the longitudinal dimension of the sidewall 50C. And substantially equal. The side wall 73A is welded to the side wall 50C. The side wall 73A may be attached to the side wall 50C by a screw or the like.

  The protection portion 74 has a side wall 74A facing the surface opposite to the surface held by the holding portion 73 of the heat insulating material 71, and an upper wall 74B and a bottom wall projecting to the rear of the fire door 1 from the side wall 74A. And 74C. The side wall 74A, the top wall 74B and the bottom wall 74C are shaped to extend in the driving direction ZB of the sliding door 20, and the longitudinal dimension is the longitudinal dimension of the heat insulating material 71 and the longitudinal dimension of the sidewall 50C. And substantially equal.

  As shown in FIGS. 2 and 5, two heat insulating materials 71 are covered by the holding member 72 by combining the holding portion 73 and the protection portion 74 with each other. Thus, the holding member 72 is configured to hold the shape of the heat insulating material 71.

The operation and effect of the fire door 1 will be described with reference to FIG.
In the present embodiment, of the space partitioned by the fire door 1 in the building where the fire door 1 is installed, the space facing the cosmetic cover 43 is an outdoor space, and the space facing the inspection cover 42 is an indoor space The case where a fire occurs in the outdoor space will be described as an example.

  When a fire occurs in the outdoor space, the heat insulating material 71 suppresses the transmission of the heat of the flame that faces the side wall 50C through the heat insulating portion 70 of the main case 50 to the main case 50. Further, the heat transfer to the main case 50 of the heat of the flame that faces the bottom wall 50A of the main case 50 is suppressed by the heat insulating material 61. As described above, the transmission of heat of the flame to the main case 50 is suppressed by the heat insulators 61 and 71, so the temperature inside the main case 50 is unlikely to rise. Therefore, the temperature of the drive unit 30 does not easily rise.

The fireproof door 1 of the present embodiment has the following effects.
(1) Since the holding member 72 formed of stainless steel having a thermal conductivity lower than that of a general steel material such as mild steel is disposed between the main case 50 and the heat insulating material 71, the holding member 72 is interposed. The transfer of heat to the main case 50 is suppressed, and the temperature inside the main case 50 can be suppressed from rising. Therefore, the temperature of the drive unit 30 does not easily rise.

  (2) An air layer is formed between the adjacent heat insulating materials 71 by laminating the heat insulating materials 71 in the front-rear direction ZC of the fire door 1. For this reason, in addition to the heat insulation effect by the heat insulating material 71, the heat insulation effect by the air layer is obtained, so the temperature of the drive unit 30 is more difficult to rise.

  (3) When a fire occurs in the outdoor space, the side wall 50C of the main case 50 is easily exposed to a flame. According to the fireproof door 1, the holding member 72 is attached to the side wall 50C of the main case 50, so the heat insulator 71 is disposed at a position facing the side wall 50C. Thus, since the heat insulating material 71 is arrange | positioned in the location which is easy to be exposed to the flames of the fire door 1, the temperature of the drive part 30 does not rise easily more.

  (4) Since the heat insulating material 71 and the holding member 72 are shaped to extend along the side wall 50C of the main case 50, the heat insulating material 71 and the holding member 72 are disposed at a position facing the wider portion of the main case 50. Ru. For this reason, the temperature of the drive unit 30 is less likely to rise.

  (5) Since the holding member 72 is configured to hold the shape of the heat insulating material 71, the shape of the heat insulating material 71 is easily maintained. For this reason, it can suppress that the heat insulation material 71 is exposed to a flame, a shape collapse | crumbles, and the heat insulation performance of the heat insulation material 71 falls.

  (6) Since the heat insulating material 71 is prevented from being directly exposed to the flame by the protective portion 74, the shape of the heat insulating material 71 is easily maintained. For this reason, it can suppress that the heat insulation material 71 is exposed to a flame, a shape collapse | crumbles, and the heat insulation performance of the heat insulation material 71 falls.

  (7) Since the protective portion 74 is shaped to extend along the side wall 50C of the sliding door 20, the protective portion 74 can cover a wider portion of the surface of the heat insulating material 71 exposed to the flame. Therefore, the shape of the heat insulating material 71 can be more easily maintained.

  (8) Since the air layer 54 is formed in the space inside the main case 50 by the first partition plate 52 and the second partition plate 53, the heat transfer inside the main case 50 is achieved by the air layer 54. It is inhibited. In addition, since the first partition plate 52 and the second partition plate 53 are formed of stainless steel having a thermal conductivity lower than that of a general steel material such as mild steel, more heat is transmitted inside the main case 50. It is hard to be done. Therefore, the temperature of the drive unit 30 does not easily rise.

  (9) Since the heat insulating material 61 supported by the sub case 60 is provided inside the sub case 60, the heat of the flame transmitted to the sub case 60 is transmitted to the space inside the sub case 60. It is suppressed by 61. Therefore, the temperature of the drive unit 30 does not easily rise.

  (10) In the driving direction ZB of the sliding door 20, when the position of the joint 71A and the position of the joint 71B are the same, heat may be transmitted to the main case 50 through the joints 71A and 71B. On the other hand, in the fire door 1, the position of the joint 71 A and the position of the joint 71 B are different in the drive direction ZB of the sliding door 20.

  (11) The heat insulators 61 and 71 are directly or indirectly supported by the main case 50 without contacting the drive unit 30 and at least partially covering the drive unit 30. For example, the heat insulating material 61 is disposed below the lowermost end of the drive unit 30. The heat insulator 71 is disposed outside the drive unit 30. According to this arrangement, at the time of a fire, the drive unit 30 is less likely to be heated by the shielding of the heat insulators 61 and / or 71.

  (12) As in the example of FIG. 2, the heat insulating material 71 may be disposed to cross or cover the drive unit 30 in the height direction ZA. For example, the upper end of the heat insulating material 71 is located above the uppermost part of the drive unit 30 (for example, the uppermost part of the electric motor 31), and the lower end of the heat insulator 71 is the lowermost part of the drive unit 30 (for example, the lowermost part It may be located lower than). According to this arrangement, at the time of a fire, the drive unit 30 is less likely to be heated by the shielding of the heat insulating material 71.

  (13) The heat insulators 61, 71 are directly or indirectly supported by the main case 50 without contacting the second partition plate 53 and at least partially covering the second partition plate 53. Ru. For example, the heat insulating material 61 is disposed below the lowermost end of the second partition plate 53. The heat insulating material 71 is disposed outside the second partition plate 53. According to this arrangement, the wiring on the second partition plate 53 (the wiring of the drive unit 30 and / or the wiring of the sensor) is less likely to be heated by the shielding of the heat insulating material 61 and / or 71 when a fire occurs.

  (14) As in the example of FIG. 2, the heat insulating material 71 may be disposed to cross or cover the second partition plate 53 in the height direction ZA. According to this arrangement, at the time of a fire, the wiring on the second partition plate 53 (the wiring of the drive unit 30 and / or the wiring of the sensor) is less likely to be heated by the shielding of the heat insulating material 71.

(Modification)
The above description of the embodiment is an illustration of possible forms of the door according to the present invention, and is not intended to limit the form. The door according to the present invention may take, for example, a combination of the modification of the embodiment shown below and at least two modifications not contradictory to each other. 6 to 12 and 15 to 25, only the main case 50 and the heat insulating portion 70 are illustrated with respect to the blind 40 for simplification of the drawing.

(Modification 1)
In the embodiment described above, the component formed of stainless steel among the components constituting the fire door 1 may be formed of any metal material other than stainless steel. The optional metal material is preferably a metal such as titanium having a thermal conductivity lower than that of a general steel material such as mild steel.

(Modification 2)
In the above embodiment, the arrangement and the shape of the heat insulating material 71 may be, for example, as shown in (a) to (p) below.

(A) As shown in FIG. 6, the heat insulating material 71 may be attached directly to the bottom wall 50A of the main case 50. That is, the fire lock door 1 of this modification does not have the holding member 72.
(B) As shown in FIG. 7, the heat insulating material 71 may be directly attached to the side wall 50 </ b> B of the main case 50. That is, the fire lock door 1 of this modification does not have the holding member 72.

(C) As shown in FIG. 8, the heat insulating material 71 may be directly attached to the side wall 50 </ b> C of the main case 50. That is, the fire lock door 1 of this modification does not have the holding member 72.
(D) As shown in FIG. 9, the heat insulator 71 may be directly attached to the upper wall 50D of the main case 50. That is, the fire lock door 1 of this modification does not have the holding member 72.

(E) As shown in FIG. 10, the heat insulating material 71 may be attached to the bottom wall 50A of the main case 50 via the holding member 72.
(F) As shown in FIG. 11, the heat insulator 71 may be attached to the side wall 50B of the main case 50 via the holding member 72.

(G) As shown in FIG. 12, the heat insulator 71 may be attached to the upper wall 50D of the main case 50 via the holding member 72.
(H) As shown in FIG. 13, the longitudinal dimension of the heat insulating material 71 may be longer than the longitudinal dimension of the side wall 73A, the top wall 73B, and the bottom wall 73C of the holding portion 73. According to the fireproof door 1 of this modification, since the heat insulating material 71 is disposed in a wider range, the heat insulating effect is further enhanced.

  (I) As shown in FIG. 14, the longitudinal dimension of the heat insulating material 71 may be shorter than the longitudinal dimensions of the side wall 73A, the top wall 73B, and the bottom wall 73C of the holding portion 73. In the fire door 1 of this modification, the heat insulating material 71 is preferably disposed in a portion corresponding to the drive unit 30 (see FIG. 2). According to the fire prevention door 1 of this modification, weight reduction of the heat insulation part 70 is achieved.

  (J) As shown in FIG. 15, the dimension in the longitudinal direction of the heat insulator 71 may be longer than the dimension in the longitudinal direction of the side wall 50C of the main case 50. According to the fire lock door 1 of this modification, since the heat insulating material is disposed in a wider range, the heat insulating effect is further enhanced.

  (K) As shown in FIG. 16, the longitudinal dimension of the heat insulating material 71 may be shorter than the longitudinal dimension of the side wall 50C of the main case 50. In the fire door 1 of this modification, the heat insulating material 71 is preferably disposed in a portion corresponding to the drive unit 30 (see FIG. 2). According to the fire prevention door 1 of this modification, weight reduction of the heat insulation part 70 is achieved.

  (L) As shown in FIG. 17, the heat insulator 71 may be attached to the side wall 50C via the holding member 72 disposed inside the main case 50. In the fire door 1 of this modification, the holding member 72 may be omitted, and the heat insulating material 71 may be directly attached to the side wall 50 C inside the main case 50.

  (M) As shown in FIG. 18, the heat insulating material 71 may be attached to the side wall 50 </ b> B via the holding member 72 disposed inside the main case 50. In the fire door 1 of this modification, the holding member 72 may be omitted, and the heat insulating material 71 may be directly attached to the side wall 50 B inside the main case 50.

  (N) As shown in FIG. 19, the heat insulating material 71 may be attached to the upper wall 50D via the holding member 72 disposed inside the main case 50. In the fire door 1 of this modification, the holding member 72 may be omitted, and the heat insulating material 71 may be directly attached to the upper wall 50 D inside the main case 50.

  (O) As shown in FIG. 20, the heat insulating material 71 may be attached to the bottom wall 50A via the holding member 72 disposed inside the main case 50. In the fire door 1 of this modification, the holding member 72 may be omitted, and the heat insulating material 71 may be directly attached to the bottom wall 50A inside the main case 50.

(P) As shown in FIG. 21, the heat insulating material 71 may be stacked in the height direction ZA of the fire door 1.
(Modification 3)
In the above embodiment, the shape and dimensions of the holding member 72 may be, for example, as shown in (a) to (f) below.

(A) As shown in FIG. 22, the fire door 1 of the modified example is provided with a pair of holding members 172 arranged at intervals in the driving direction ZB of the sliding door 20.
The holding member 172 is made of, for example, stainless steel. The holding member 172 is attached to the side wall 50C of the main case 50, and is formed at a longitudinal end of the case attachment portion 172A extending in the height direction ZA of the fire door 1 and the case attachment portion 172A. A pair of supporting portions 172B to support is provided. In the height direction ZA of the fire door 1, the pair of support portions 172B is formed at an interval. That is, in the height direction ZA of the fire door 1, the dimension of the pair of support portions 172B is shorter than the dimension of the case attachment portion 172A. The case attachment portion 172A may be welded to the side wall 50C of the main case 50, or may be fixed by a bolt. The heat insulating material 71 is inserted between the pair of support portions 172 </ b> B and is covered by the cosmetic cover 43 attached to the main case 50.

  According to the fire door 1 of this modification, the heat insulating material 71 is supported by the main case 50 via the pair of divided holding members 172, so that the weight of the fire door 1 can be reduced. Further, in the height direction ZA of the fire door 1, the dimensions of the pair of support portions 172B are shorter than the dimensions of the case attachment portion 172A, so that the weight of the holding member 172 can be reduced. In the fire door 1 of this modification, three or more holding members 172 may be arranged at predetermined intervals along the driving direction ZB of the sliding door 20. Further, as shown in FIG. 23, the shape of the holding member 172 may be a shape in which the case attachment portion 172A and the support portion 172B extend in the driving direction ZB of the sliding door 20. Also according to this configuration, since the gap is formed between the pair of support portions 172B, the weight of the holding member 172 can be reduced.

(B) As shown in FIG. 24, the fire door 1 of the modified example includes a pair of holding members 272 spaced apart in the height direction ZA of the fire door 1.
The holding member 272 is formed of, for example, stainless steel. The holding member 272 includes a case attachment portion 272A attached to the side wall 50C of the main case 50, and a support portion 272B which is formed at an end of the case attachment portion 272A in the short direction and supports the heat insulating material 71.

  The dimension of the case attachment portion 272A of the holding member 272 disposed below the pair of holding members 272 in the height direction ZA of the fire door 1 is disposed above the pair of holding members 272. It is longer than the dimension of the case attachment portion 272A of the holding member 272. In the height direction ZA of the fire door 1, the dimension of the pair of support portions 272B is shorter than the dimension of the case attachment portion 272A. The case attachment portion 272A may be welded to the side wall 50C of the main case 50, or may be fixed by a bolt. The heat insulating material 71 is inserted between the support portions 272B and is covered by the cosmetic cover 43 attached to the main case 50.

  According to the fire door 1 of this modification, the heat insulating material 71 is supported by the main case 50 through the pair of divided holding members 272, so that the weight of the fire door 1 can be reduced. Further, in the height direction ZA of the fire door 1, the dimensions of the pair of support portions 272B are shorter than the dimensions of the case attachment portion 272A, so that the weight of the support portions 272B can be reduced. As shown in FIG. 25, the holding member 272 may be arranged at a predetermined interval along the driving direction ZB of the sliding door 20. The number of holding members 272 arranged at predetermined intervals along the driving direction ZB of the sliding door 20 may be three or more.

  (C) The longitudinal dimension of the holding portion 73 can be any dimension. For example, when the dimension in the longitudinal direction of the holding portion 73 is longer than the dimension in the longitudinal direction of the side wall 50C of the main case 50, the heat insulating material 71 can be disposed in a wider range. On the other hand, for example, when the dimension in the longitudinal direction of the holding portion 73 is shorter than the dimension in the longitudinal direction of the side wall 50C of the main case 50, weight reduction of the fire door 1 is achieved.

  (D) The longitudinal dimension of the protective portion 74 may have any dimension. For example, when the dimension in the longitudinal direction of the protective portion 74 is longer than the dimension in the longitudinal direction of the side wall 50C of the main case 50, the protective portion 74 can cover the heat insulating material 71 in a wider range. It can suppress more that the heat insulation performance of 71 falls. On the other hand, for example, when the dimension in the longitudinal direction of the protective portion 74 is shorter than the dimension in the longitudinal direction of the side wall 50C of the main case 50, the weight reduction of the fire door 1 is achieved.

(E) As shown in FIG. 26, the holding portion 73 and the protection portion 74 can be integrally formed, for example, as a single member.
(F) The holding member 72 may not have the holding portion 73 or the protection portion 74. When the holding member 72 does not have the holding portion 73, the heat insulating material 71 is directly attached to the main case 50. On the other hand, when the holding member 72 does not have the protection portion 74, the heat insulating material 71 is covered by the cosmetic cover 43.

  The subject matter of the invention may reside in less than all features of the specific embodiments and variations described above. For example, although stainless steel was used as an example of high alloy steel in embodiment and some modifications, steel materials other than stainless steel can be used. Although mild steel (mild steel) is used as an example of a general steel material in embodiment and some modifications, steel materials other than mild steel can be used. For example, in place of stainless steel and / or mild steel, fire resistant steel, heat resistant steel, hot dip galvanized steel, electro-galvanized steel, etc. Can be used. The scope of the present invention should be determined along with the full scope of claims and equivalents.

1: Fire door 20: Sliding door
30: Drive unit 50: Main case (case)
50C: Side wall 52: First partition plate 60: Sub case (case)
61: Thermal insulation 71: Thermal insulation 72, 172, 272: Holding member 73: Holding portion 74: Protective portion

Claims (9)

A drive for driving the door,
A case accommodating the drive unit;
A heat insulating material supported by the case outside the case ;
Than mild steel and a holding member which thermal conductivity is formed by the lower metal,
The holding member includes a portion disposed between the case and the heat insulating material,
The heat insulating material is supported by the case via the holding member. The holding member is attached to the side wall of the case
The fire lock door according to claim 1 . At least one of the heat insulating material and the holding member is shaped to extend along the side wall of the case.
The fire lock door according to claim 1 or 2 . The holding member is configured to hold the shape of the heat insulating material
The fire door according to any one of claims 1 to 3 . The holding member is a holding portion which is a portion disposed between the case and the heat insulating material, and protection facing the surface opposite to the surface held by the holding portion of the heat insulating material. Equipped with
The fire door according to any one of claims 1 to 4 . The protective portion is shaped to extend along the side wall of the case.
The fire lock door according to claim 5 . A plurality of the holding members are provided, and the plurality of holding members are spaced apart.
The fire door according to any one of claims 1 to 6 . The case is further formed of a metal having a thermal conductivity lower than that of mild steel, and further provided with a partition plate spaced from the inner surface of the case inside the case.
The fire door according to any one of claims 1 to 7 . A plurality of the heat insulating materials are provided, and the plurality of heat insulating materials are stacked in the front-rear direction of the fire door
The fire door according to any one of claims 1 to 8 .

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